clear all;
A = [1 1/exp(1) 1/exp(2)]; % power delay profile
N = 64; % number of symbols in a single OFDM symbol
GI = 16; % guard interval
Mt = 1; % number of Tx antennas
Mr = 1; % number of Rx antennas
Mt1 = 2; % number of Tx antennas
Mr1 = 2; % number of Rx antennas
sig2 = 1e-3; % noise variance
M = 8; % max constellation bit number
Mgap = 10.^(1:(1.7/10):2.7); % gap
Btot = 100*Mt; % total # bits per OFDM symbol
TransmitIter = 5; % # iterations of symbol transmissions for each channel instance
ChannelIter = 10; % # iterations of independent identically distributed channel instances
GapIter = length(Mgap);
load ENC2.mat
load ENC4.mat
load ENC16.mat
load ENC64.mat
load ENC256.mat
TotEbNo = [];
MIMO_TotEbNo = [];
Errors =[];
MIMO_Errors=[];
EbNo = [];
MIMO_EbNo = [];
for lGap = 1:GapIter
lGap
gap = Mgap(lGap);
totalErrors = 0;
MIMO_totalErrors = 0;
for lChan = 1:ChannelIter
% create channel
[H h_f]=create_channel(Mt, Mr, A, N+GI);
[H1 h_f1]=create_channel(Mt1, Mr1, A, N+GI);
% decompose each subchannel in the frequency domain
[U S V] = svd_decompose_channel(Mt, Mr, h_f, N);
[U1 S1 V1] = svd_decompose_channel(Mt1, Mr1, h_f1, N);
% bitloading
[bits_alloc,energy_alloc] = BitLoad(S,Btot,Mt*N,gap,sig2,M);
[bits_alloc1,energy_alloc1] = BitLoad(S1,Btot,Mt1*N,gap,sig2,M);
%energy_alloc=energy_alloc/(mean(energy_alloc));
%energy_alloc=ones(1,128);
for lTrans = 1:TransmitIter
% bits to transmit
x = (randn(1,Btot)>0);
% modulate
x_mod = modulate(x,bits_alloc,energy_alloc, s2,s4,s16,s64,s256);
mod_symbols = modulate(x,bits_alloc1,energy_alloc1,s2,s4,s16,s64,s256); %fix QPSK modulate
% precode modulated signal
x_pre = precode(Mt, x_mod, V, N);
symbols_pre = precode(Mt1, mod_symbols, V1, N);
% ifft, with cyclic prefix for each antenna
ofdm_symbol =[];
MIMO_ofdm_symbol =[];
for i=1:Mt
ofdm_symbol = [ofdm_symbol; ifft_cp_tx_blk(x_pre(i:Mt:Mt*(N-1)+i),N,GI)];
end
for i=1:Mt1
MIMO_ofdm_symbol = [MIMO_ofdm_symbol; ifft_cp_tx_blk(symbols_pre(i:Mt1:Mt1*(N-1)+i),N,GI)];
end
ofdm_symbol2 = reshape(ofdm_symbol,Mt*(N+GI),1);
MIMO_ofdm_symbol2 = reshape(MIMO_ofdm_symbol,Mt1*(N+GI),1);
% channel
y = transpose(channel(sig2, Mt, Mr, ofdm_symbol2, H, N+GI));
z = transpose(channel(sig2, Mt1, Mr1, MIMO_ofdm_symbol2, H1, N+GI));
% fft
rec_symbol =[];
MIMO_rec_symbol =[];
for i=1:Mt
rec_symbol = [rec_symbol; fft_cp_rx_blk(y(i:Mt:Mt*(N+GI-1)+i),N,GI)];
end
for i=1:Mt1
MIMO_rec_symbol = [MIMO_rec_symbol; fft_cp_rx_blk(z(i:Mt1:Mt1*(N+GI-1)+i),N,GI)];
end
rec_symbol2 = reshape(rec_symbol,1,Mt*N);
MIMO_rec_symbol2 = reshape(MIMO_rec_symbol,1,Mt1*N);
% shape received signal
shaped_vals = shape(rec_symbol2, Mr, U, N);
MIMO_shaped_vals = shape(MIMO_rec_symbol2, Mr1, U1, N);
% demodulate
y_demod = demodulate(shaped_vals, bits_alloc, energy_alloc, S, s2,s4,s16,s64,s256, c2,c4,c16,c64,c256);
z_demod = demodulate(MIMO_shaped_vals, bits_alloc1, energy_alloc1,S1, s2,s4,s16,s64,s256, c2,c4,c16,c64,c256);
% comparison
totalErrors = totalErrors + sum(xor(y_demod,x));
MIMO_totalErrors = MIMO_totalErrors + sum(xor(z_demod,x));
end
EbNo = [EbNo sum(energy_alloc)/Btot/sig2];
MIMO_EbNo = [MIMO_EbNo sum(energy_alloc1)/Btot/sig2];
end
Errors = [Errors totalErrors/Btot/ChannelIter/TransmitIter]
MIMO_Errors = [MIMO_Errors MIMO_totalErrors/Btot/ChannelIter/TransmitIter]
TotEbNo = [TotEbNo mean(EbNo)]
MIMO_TotEbNo = [MIMO_TotEbNo mean(MIMO_EbNo)]
EbNo = [];
MIMO_EbNo = [];
end
plot(TotEbNo, Errors,'r+:',MIMO_TotEbNo,MIMO_Errors,'b*--');
legend('SISO adative','MIMO adative');
xlabel('Eb/No');
ylabel('BER');
title('SISO-MIMO link, adaptive rate and power')
save SISO_adaptive2.mat Errors EbNo
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